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LAPAROSCOPIC-ASSISTED COLECTOMY
IN HEART TRANSPLANT RECIPIENTS.
O. DETRY MD1, 3, J.O. DEFRAIGNE MD1,M.MEURISSE MD3,
J. D. CHICHE MD2, J. JORIS MD2
P. HONORE MD3, N. JACQUET MD 3, R. LIMET MD1
1 University Hospital of Liège,
Department of Cardiovascular Surgery (Professor R. Limet)
2 University Hospital of Liège,
Department of Anesthesia and Intensive Care Medicine (Professor M. Lamy)
3 University Hospital of Liège,
Department of Abdominal Surgery and Transplantation (Professor N. Jacquet)

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Detry O, Defraigne JO, Meurisse M, Chiche JD, Joris J, Honoré P, Jacquet N, Limet R.

Laparoscopic-assisted colectomy in heart transplant recipients.

Clin Transplantation

Abstract: Reports of laparoscopy in heart graft recipients are scarce and to our knowledge, laparoscopic colectomy has not yet been reported in heart transplanted patients. The magnitude and the tolerance of the hemodynamic changes induced by pneumoperitoneum are unknown in heart graft recipients, who have denervated heart and are "preload dependent". The authors report the clinical courses of two heart graft recipients who developed acutediverticulitis without perforation or peritonitis and who underwent laparoscopic-assisted colectomy without complications.

Key Words: Transplantation; Transplantation, Complication; Diverticulitis; Laparoscopy.

Correspondence to :

O. Detry M.D.
Service de Chirurgie Cardio-vasculaire
C.H.U. Liège
Domaine Universitaire du Sart-Tilman

B4000 Liège 1 (Belgium)

Phone 32 / 41 / 66.71.63

Fax 32 / 41 / 66.71.64

INTRODUCTION

Since the clinical advent of cyclosporine A in the early 1980s, orthotopic heart transplantation (OHT) has become an alternative in the treatment of end-stage cardiac failure. Long time survival of heart graft recipients is usually achieved [1]. Nevertheless, heart graft recipients are susceptible to extracardiac surgical complications [2] but fortunately, they present a moderate risk for general surgery.

The many benefits reported after laparoscopic surgery explain its increasing success and its extended use for gastrointestinal surgical procedures. Nowadays, reports present the feasibility and the effectiveness of laparoscopic colectomy [3]. Pneumoperitoneum required for laparoscopy induces several pathophysiological changes, including cardiovascular changes [4]. However, there are only few data on the hemodynamic repercussions of pneumoperitoneum in patients with previous cardiopulmonary diseases. Particularly, reports of laparoscopic procedures in heart graft recipients are scarce [5]. In these patients, potential intraoperative risks have to be balanced with postoperative benefits. We describe the clinical courses of two heart graft recipients who developed acutediverticulitis without perforation or peritonitis and who underwent laparoscopic-assisted colectomy without complications. The surgical procedures were similar to the technique described by Plasencia [6]. To our knowledge, this is the first report of laparoscopic colectomy in heart graft recipients.

METHODS

Between January 1985 and December 1994, 145 patients underwent OHT in the Cardiovascular Surgery Department of the University Hospital of Liège. Standard immunosuppression regimen consisted of triple-drug therapy with cyclosporine, corticosteroids and azathioprine. In addition, a course of antithymocyte globulin (ATG) was given prophylactically in the early posttransplantation period. Rejection episodes were diagnosed by endomyocardial biopsies and were initially treated with pulse doses of intravenous corticosteroids. ATG or monoclonal CD-3 antibodies (OKT 3) were used in steroid resistant rejections.

CASE REPORTS

Case 1: A 59-year-old man developed idiopathic dilated cardiomyopathy. His past medical history revealed a gastric ulcer and a past cytomegalovirus (CMV) infection. He underwent uneventful OHT. He was discharged from hospital at postoperative day 32with standard triple-drug immunosuppression. The azathioprine administration was interrupted a few weeks after transplantation because of leukopenia. Five years after transplantation the patient was admitted to the hospital because of abrupt onset of rectorrhage without any abdominal discomfort or pain. Nausea or vomiting were not reported. At admission, clinical examination did not reveal any abdominal symptoms. Body temperature was normal. Laboratory tests demonstrated mild inflammation [white blood count (WBC) 11,800/mm3, with 95% neutrophils, fibrinogen 4.08 g/l, C-reactive protein (CRP) 20 mg/l]. Twelve hours after admission the patient developed fever. Colonoscopy located some diverticles and fresh blood at 25 cm from the anal margin. Routine abdominal radiographs were normal. A computed tomographic (CT) scan of the abdomen revealed terminal colonic diverticulitis with a parietal abscess. Systemic broad-spectrum antibiotherapy (Amikacin 15mg.kg-1.d-1, Ornidazole 1g.d-1, Piperacillin 150mg.kg-1.d-1) was initiated. On the fourth day colonic enema revealed acute diverticulitis with abscesses and a limited parietal perforation without serosal involvment. Laparoscopic-assisted sigmoid colectomy followed by direct transanal end-to-end anastomosis was performed without complication 7 days after admission. Pathological analysis confirmed acute diverticulitis with abscesses. The patient was discharged on postoperative day 9 and no adverse event has been reported during the first year follow-up.

Case 2: A 71-year-old man underwent uneventful OHT for idiopathic dilated cardiomyopathy. His past medical history was significant for past CMV infection. The triple-drug immunosuppression regimen was introduced. Six months after transplantation, the patient developed fever with acute abdominal pain and left lower quadrant tenderness. He developed nausea and constipation. Laboratory tests showed moderate inflammation (WBC 11,200/mm3, CRP 61 mg/l). Routine abdominal radiographs were normal. Abdominal CT scan revealed acute colonic diverticulitis, with mesenteric inflammation. Barium enema confirmed the diagnosis of diverticulitis. After 11 days of intravenous broad spectrum antibiotherapy (Amoxicillin 3g.d-1 plus clavulanic acid 600mg.d-1, metronidazole 1500mg.d-1) and bowel rest, laparoscopic-assisted resection of the sigmoid colon was performed with transanal end-to-end anastomosis. Pathological analysis revealed acute diverticulitis and pericolonic abscesses. The patient was discharged at postoperative day 10 and the first year follow-up was uneventful.

Perioperative management: Both patients underwent bowel rest with nasogastric suction. Broad spectrum intravenous antibiotherapy and fluid restauration were initiated. After a few days, laparoscopic-assisted sigmoid colectomies were performed. Before induction of anesthesia, the patients were preloaded with 500 ml hydroxy-ethyl-starch 6%. Anesthesia was induced with sufentanil 20 µg and propofol 1.5mg/kg. Orotracheal intubation was facilitated by atracurium 0.5 mg/kg. Lactated Ringer's solution was infused at a rate of 4 ml.kg-1.h-1. Anesthesia was maintained with isoflurane in 50% N2O:O2. Constant muscle relaxation was achieved using atracurium 0.3 mg.kg-1.h-1. Carbon dioxide pneumoperitoneum was induced at the rate of 1l/min with the patient tilted in a 5˚ head down position. Intraabdominal pressure was maintained at 14 mmHg. The involved sigmoid colon was laparoscopically dissected through 4 trocars. During colonic dissection, infusion rate of lactated Ringer's solution was increased to 8 ml.kg-1.h-1. Dopamine infusion was used at a rate of 2 µg.kg-1.min-1.Once the distal margin of resection has been reached, the bowel was transected by an endoscopic stapler. The bowel was brought out through an incision created in the left lower quadrant. The resection of the proximal margin was performed externally. The detachable head and anvil of a circular intraluminal stapler were inserted in the lumen of the proximal bowel by tying a purse-string suture around it. Next the left lower quadrant incision was closed and the pneumoperitoneum was reestablished. The shaft of the circular stapler was passed through the anus. The head and anvil were then laparoscopically reattached to the shaft. The stapler was fired, creating a transanal double-stapled anastomosis. Both patients woke up in the postanesthetic care unit when intraoperative hypothermia was corrected.

DISCUSSION

As other immunosuppressed patients, heart graft recipients are likely to develop surgical digestive complications [2]. Recipients are susceptible to complicated colonic diverticulitis which may be favoured by the combination of the immunosuppressive drugs. Open two-stage procedures with resection of the involved colon and end-colostomy (Hartmann procedure) were classically undergone in these patients.

Two of our heart graft recipients developed diverticulitis which were diagnosed before perforation occurred. These patients underwent preparation for a few days and elective one-stage laparoscopic-assisted colectomies with primary end-to-end transanal anastomosis were performed. Postoperative outcomes were uneventful. Laparoscopic colectomy may be performed without the need for end colostomy in recipients whose diverticulitis is not complicated by perforation and peritonitis at the time of diagnosis. Laparoscopic approach may be particularly favourable in immunosuppressed patients and lead to a decrease of complications as chest and wound infections [3]. Bowel functions may return more quickly and hospital postoperative stay may be decreased. Finally, laparoscopy may lead to a reduction of the postoperative discomfort and pain [6].

Anesthetic management of heart recipients scheduled for laparoscopy must consider the physiology of the denervated heart. In the normally innervated heart, the increase in cardiac output is primarily achieved by an increase in heart rate with little change in stroke volume. Conversely, denervated heart are "preload dependent" and responds to stress primarly by increasing stroke volume [7]. Denervated heart does not respond to atropine or digoxin. Arrhytmias, both atrial and ventricular, are common in heart graft recipients. They are promoted by lack of vagal suppressant tone and increased sensitivity to catecholamines [7]. Heart rate increased in both patients during laparoscopy. This may be explained by the lack of vagal tone, and the sensitivity to the catecholamines released during pneumoperitoneum [8]. However, no patients developed arrythmias throughout the procedures.

In healthy patients, pneumoperitoneum results in a significant reduction of the venous return and an increase of systemic vascular resistance [4]. Consequently, cardiac output decreases. Whereas heart rate does not change significantly, arterial pressure increases. Both mechanical and humoral (catecholamines, vasopressine) factors contribute to these pathophysiologic changes [8]. The magnitude and the tolerance of these changes are however unknown in heart transplanted patients. Increasing circulatory blood volume reduces the decrease in venous return produced by pneumoperitoneum [9] and is, furthermore, beneficial in these "preload dependent" patients. Therefore, 500 ml of colloid solution were infused before the beginning of peritoneal insufflation. Insufflation was performed with the patient in slight head down position to further improve the venous return. A continuous infusion of atracurium was used to avoid brusque changes in the level of muscle relaxation, with consequent increases in intraabdominal pressure. Indeed, these may lead to acute ventilatory and hemodynamic changes. Increased intraabdominal pressure may produce a decrease in renal blood flow [10]. Furthermore, chronic cyclosporine treatment may also alter renal function. Therefore, dopamine infusion at a rate of 2 µg.kg-1.min-1 was used and none of our patients developed acute postoperative renal dysfunction. Monitoring of cardiac filling pressure is difficult during pneumoperitoneum. Indeed, because pneumoperitoneum also results in an increase in intrathoracic pressure, right atrial pressure and pulmonary capillary wedge pressure no longer reflect cardiac filling pressure. An infusion rate of 8 ml.kg-1.h-1 of lactated Ringer's solution was used according to our previous experience with laparoscopic colectomy in non transplanted patients.

Using this protocol, hemodynamic changes induced by pneumoperitoneum were well tolerated by both patients with well compensated transplanted heart. This good hemodynamics tolerance encourages us to propose laparoscopy to heart transplanted patients in case of uncomplicated diverticulitis. So they may benefit to the same postoperative advantages as non immunosuppressed patients such as reduced postoperative pain, pulmonary dysfunction, and respiratory or wound infections.

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